RU1809256C - Air-conditioning system - Google Patents

Abstract

SUMMARY OF THE INVENTION: A non-return valve is installed in the bypass channel and communicates with the vent line. The direct evaporative cooling heat exchanger is located indoors. The non-return valve through the control unit is connected to a temperature control sensor. An exhaust fan is located above the auxiliary flow channels, and a heater with an adjustable valve connected via a control unit to a temperature control sensor under the channels in the water tray. The second exhaust fan is located in the room, its drive is equipped with a speed controller and is connected to the control unit. The direct cooling heat exchanger is made in the form of air distributors with a layer of hygroscopic material irrigated with tap water supplied through a valve connected to a sensor. Humidity control. 1 C.p. f-ls, 1 ill.

Description

The invention relates to ventilation and air conditioning techniques.

The purpose of the invention is to ensure year-round use of the device for both evaporative cooling and heating of the fresh air outside with the heat of the air removed from the room, and also in order to save energy, the relative humidity of the air in the required number of room zones is automatically maintained.

This goal is achieved by additional placement in the device structure after the bypass channel of the connecting pipe for the intake of exhaust air with a reverse control valve located in it compared to the control valve in the bypass channel, and instead

direct evaporative cooling heat exchangers in the room air humidifiers are installed with adiabatic humidification (direct evaporative cooling) of the main air flow in the layer of hygroscopic material irrigated with tap water and regulation of tap water supply. For irrigation, the number of indoor air humidity sensors instructs must be equal to or greater than the required number of zones for controlling the relative humidity of the air in the room.

The drawing shows a structural diagram of the proposed device for two-stage evaporative cooling and heating of the supply air. Consistently along the supply air

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In the installation 1 and room 2, respectively, a tubular heat exchanger 3 for indirectly evaporative cooling or heating of the supply air and a layer irrigated with tap water in the air diffuser-humidifier 4 for direct evaporative cooling — adiabatic humidification of the supply air are respectively located. The heat exchanger 3 has channels 5 and 6, respectively, of the general and auxiliary (or removable - dashed line) air flows. After the heat exchanger 3 is a chamber 7 separation of air flow s. the bypass channel 8 and the reciprocal adjustable valves 9 located therein for bypassing the auxiliary GB and 10 for receiving the Gy exhaust air flow: The supercharger 11 with the actuator 12 is connected by an inlet 1.3 to the atmosphere, and by an outlet 14 to the general air flow channels 14c. Reciprocal valves 9 and 10 through the control unit 15 are connected to the sensor 16 for monitoring the air temperature tB in room 2, where the sensors 17 monitor the air humidity in the zones. The drawing shows two air humidity control zones YB1 and UV2 according to the number of humidifier diffusers 4, to which tap water is connected through pipelines 18 and valves 19 are mounted on pipelines 18. Connected to humidity control sensors 17. Excess air from room 2 is removed by the roof ventilator 20 or through an exhaust duct 21 connected to the inlet 22 at the inlet to the adjustable valve 10.. Under the channels 6 there is a drip tray 23 for collecting water taken by the pump 24 and supplied through the pipeline 25 to the upper cut of the channels 6, after which the separators 26 and the axial fan 27 are mounted. At the blower 11 and the exhaust fan 20, controllers 28 are installed to control the number of revolutions of the electric motors of these fans according to. the command of the sensor 16 controls the air temperature in the room 2, which, through the controller 15, is connected to an automatic valve 30 on the heat supply line to the heat exchanger 29 in the pallet 23 of the installation 1, Installation 1 and the devices connected with it operate as follows:

During the warm season, room 2 has excess heat and it is required to supply cooled and humidified fresh air supply Spn, which is provided by operation from the electric motor 12 of the supercharger 11, which draws through the inlet 13 a common stream consisting of the main Spn and auxiliary

GB of air flows, which, through outlet 14, enter the common channel 5 of the tubular heat exchanger 3, where the total flow gives off the heat through the tube

heat exchanger 3 to the irrigation water and the auxiliary air flow passing inside the channels 6, where the auxiliary air flow enters the nocnle of separation in the chamber 7 and passage of0 of the indoor valves 9 and the bypass channel §, and the irrigation water flows into the $ 2 pan, from where the water pump 24 through a pipe 2§ is fed to the upper cut of the channels 6 and 1 of the separator 26 are kept water droplets I

5, the humidified auxiliary air flow from the operation of the fan 27 is emitted into the atmosphere, and the cooled supply air Spn is supplied to the air distributors of the m-humidifiers 4, where the passage irrigated by the tap water is absorbed adiabatically moistened upon complete evaporation of the irrigation tap water, the flow of which is supplied to the pipeline 18 is controlled by valve t 9,

5 controlled by the command of the sensor 17 to control the air humidity in the controlled area of the room 2, from which the excess air is removed from the operation of the exhaust fan 20. When the temperature decreases

0 of outdoor air, it is necessary to reduce the degree of cooling of the supply air in the heat exchanger 3, which is carried out by the command of the sensor 16 to control the humidity in the room 2 through the control unit 5, a command is issued to the controllers 28 and the number of revolutions of the electric drive motor of the blower 1-1 decreases and. exhaust fan 20, which leads to a corresponding reduction in the costs of the direct Spn. removable Gy and auxiliary GB air flows. With a further decrease in the outdoor temperature, a command is issued via the control unit 15 to move reciprocal

5 valves 9 and 10, which will ensure a decrease in the supply to the bypass channel 8 through the shut-off valve 9 of the auxiliary air flow and the intake through the exhaust duct 21 through

0 connecting pipe 22 and opening valve 10 of the part of the removed air flow.

Under conditions of low outdoor temperatures, the exhaust fan 20 stops and all the removed air Gy no to the duct 21 through the nozzle 22 and the open valve 10 passes through the bypass channel 8 into the channels 6 of the heat exchanger 3, through which through the channels 5 passes only at outdoor air SPnh (shown poon

), and valve 9 is completely closed, and the heat from the removed Gyx air and from the irrigation water is transferred through the walls of the channels of the channels 6 to heat the fresh air in the outside, and if this heat is insufficient to maintain the temperature of the air controlled by the sensor 16, then through the block control 15 is followed by a command to open the valve 30 and, accordingly, supply heat to the heat exchanger 29 installed in the pallet 23 of the installation 1.,

Claims (2)

Formula of the invention 1. An air conditioning system containing sequentially distributed along the air flow water-cooled heat exchangers of indirect evaporative and direct evaporative cooling, the first of which has channels for general and auxiliary air flows, an air flow separation chamber with a bypass channel and located in a control valve, a supercharger with a drive, connected by an inlet to the atmosphere, and an outlet - with channels of the general air flow, and the control valve through the control unit under for prison to the sensor indoor air and the secondary air flow channels communicated with the atmosphere, and a heat exchanger potokaisparitelnogo direct cooling room -c, h and dtli moiety and 0 5 0 5 0 ;;: so that in order to ensure the supply air is heated with excess heat in the room, the additional / 1n1t1 system contains a non-return valve, a sensor for controlling felviniepa- ture and air humidity in the room, exhaust fans, a heater with an adjustable valve and an air line from the room, the non-return valve is installed in the bypass channel and communicates with the air exhaust line, the direct evaporative cooling heat exchanger is located in the room, and the non-return valve is connected via the control unit to the temperature control sensor. an exhaust fan is placed above the auxiliary flow channels, and a heater with an adjustable valve connected through a control unit to a temperature control sensor is located under the channels in the water tray, the second exhaust fan is located in the room and its drive is equipped with a frequency controller rotation and is connected to the control unit. 2. The system according to claim 1, wherein the direct cooling heat exchanger is made in the form of air distributors with a layer of absorbent material irrigated with tap water supplied through a valve connected to an air humidity control sensor. . : -,.  ---- IJ-- I .... J Editor Compiled by A. Rzayev Tehred M. Morgenthal Proofreader L. File